Contribution of serine, folate and glycine metabolism to the ATP, NADPH and purine requirements of cancer cells.

Recent observations on cancer cell metabolism indicate increased serine synthesis from glucose as a marker of poor prognosis. We have predicted that a fraction of the synthesized serine is routed to a pathway for ATP production. The pathway is composed by reactions from serine synthesis, one-carbon (folate) metabolism and the glycine cleavage system (SOG pathway). Here we show that the SOG pathway is upregulated at the level of gene expression in a subset of human tumors and that its level of expression correlates with gene signatures of cell proliferation and Myc target activation. We have also estimated the SOG pathway metabolic flux in the NCI60 tumor-derived cell lines, using previously reported exchange fluxes and a personalized model of cell metabolism. We find that the estimated rates of reactions in the SOG pathway are highly correlated with the proliferation rates of these cell lines. We also observe that the SOG pathway contributes significantly to the energy requirements of biosynthesis, to the NADPH requirement for fatty acid synthesis and to the synthesis of purines. Finally, when the PC-3 prostate cancer cell line is treated with the antifolate methotrexate, we observe a decrease in the ATP levels, AMP kinase activation and a decrease in ribonucleotides and fatty acids synthesized from [1,2-(13)C2]-D-glucose as the single tracer. Taken together our results indicate that the SOG pathway activity increases with the rate of cell proliferation and it contributes to the biosynthetic requirements of purines, ATP and NADPH of cancer cells.

Epothilone induced cytotoxicity is dependent on p53 status in prostate cells.

BACKGROUND: Epothilones are a promising class of drugs in clinical trials of prostate cancer that target the microtubules, similar to taxanes, and induce apoptosis in taxane resistant tumors. The tumor suppressor p53 is one important molecular mechanism of chemotherapy resistance that in some studies predicted tumor sensitivity to paclitaxel. We hypothesized that epothilone induced cytotoxicity would be influenced by the status of p53 in prostate cells. METHODS: LNCaP, DU145, and a transformed rat prostate (RP) epithelial cell line with a temperature sensitive mutant p53 (val 135) were studied for the effect of epothilone on cell viability, cell cycle, and cell cycle checkpoint proteins. RESULTS: Epothilone had greater cytotoxicity in p53 mutant cancer cells compared to wild type cells. We confirmed our findings by creating a transformed RP epithelial cell line with a temperature sensitive mutant p53 (val 135). Using a tetrazolium (MTT) assay we found that epothilone (100 nM) decreased cell viability in RP cells by 90% with mutant p53 compared to 45% with wild type p53 (P < 0.01). Epothilone induced G2/M arrest in 50% of cells with mutant p53 compared to 25% with wild type p53 (P < 0.01). To begin to understand mechanism of epothilone induced G2/M arrest, we assessed cell cycle checkpoint proteins. We found that the effect to enhance G2/M cell cycle arrest was associated with dephosphorylation of cdc2 in both p53 wild type and p53 mutant RP cells. CONCLUSIONS: These results demonstrate that epothilone is more active against transformed prostate epithelial cells with mutant compared to wild type p53. Epothilone is capable of dephosphorylation of cdc2 in both p53 wild type and mutant cells, which is associated with G2/M cell cycle arrest. These data provide a basis for further study of p53, and the phosphorylation status of cdc-2, as markers for epothilone sensitivity in clinical studies.